4Laboratory of Angiogenesis and Neurovascular Link, Vesalius Research Center, VIB, 3000 Leuven, Belgium, 5Laboratory of Angiogenesis and Neurovascular Link, Vesalius Research Center, Department of Oncology, University of Leuven, 3000 Belgium, and

Abstract

Prominin-1 (CD133) is commonly used to isolate stem and progenitor cells from the developing and adult nervous system and to identify cancer stem cells in brain tumors. However, despite extensive characterization of Prominin-1+ precursor cells from the adult subventricular zone, no information about the expression of Prominin-1 by precursor cells in the subgranular zone (SGZ) of the adult hippocampus has been available. We show here that Prominin-1 is expressed by a significant number of cells in the SGZ of adult mice in vivo and ex vivo, including postmitotic astrocytes. A small subset of Prominin-1+ cells coexpressed the nonspecific precursor cell marker Nestin as well as GFAP and Sox2. Upon fluorescence-activated cell sorting, only Prominin-1/Nestin double-positive cells fulfilled the defining stem cell criteria of proliferation, self-renewal, and multipotentiality as assessed by a neurosphere assay. In addition, isolated primary Prominin-1+ cells preferentially migrated to the neurogenic niche in the SGZ upon transplantation in vivo. Finally, despite its expression by various stem and progenitor cells, Prominin-1 turned out to be dispensable for precursor cell proliferation in vitro and in vivo. Nevertheless, a net decrease in hippocampal neurogenesis, by ∼30% was found in Prominin-1 knock-out mice, suggesting other roles in controlling adult hippocampal neurogenesis. Remarkably, an upregulation of Prominin-2 was detected in Prominin-1-deficient mice highlighting a potential compensatory mechanism, which might explain the lack of severe symptoms in individuals carrying mutations in the Prom1 gene.

Introduction

By many standards Prominin-1 is considered one of the most valuable “neural stem cell markers.” Based on Prominin-1 expression, stem cells can be prospectively isolated from the fetal (Uchida et al., 2000) and adult subventricular zone (SVZ) (Beckervordersandforth et al., 2010; Obermair et al., 2010), the postnatal cerebellum (Lee et al., 2005), and brain tumors (Singh et al., 2004). The function of Prominin-1, however, has not yet been fully unraveled and its role in the context of adult neurogenesis in the two “canonical” neurogenic zones of the adult brain, the SVZ of the lateral ventricles and the subgranular zone (SGZ) of the dentate gyrus in the hippocampal formation, remains unclear.

In the adult SVZ, astrocyte-like stem cells (B-cells) have a radial morphology, including an apical process bearing Prominin-1-expressing primary cilia (Beckervordersandforth et al., 2010). The SGZ of the dentate gyrus also contains a radial glia-like precursor cell (Type-1), but adult hippocampal neurogenesis has little in common with neurogenesis in the adult SVZ (Kempermann (2011), summarized in their Table 8-2). During development the stem cells for the future adult SGZ become displaced from the ventricular wall and form an ectopic germinative matrix. At least a subset of these cells is cilia bearing (Breunig et al., 2008), possibly suggesting the existence of a defined apical region, equivalent to the counterpart in the SVZ precursor cells. In a genetic association study we had found Prominin-1 expression in the brain to correlate with adult hippocampal neurogenesis in mice (Kempermann et al., 2006). Moreover, Prominin-1 was a cis-acting gene, and these genes are hypothesized to have strong, almost monogenic influences on the phenotypes with which they are associated. The question thus arose whether Prominin-1 would also be expressed by the stem cells of the SGZ as it is in the SVZ.

We thus undertook the present study to resolve the question of Prominin-1-expression in the adult murine hippocampus and its usefulness to identify and prospectively isolate precursor cells of the SGZ.

Materials and Methods

Animals.

C57BL/6 mice were originally obtained from Charles River. Prominin-1−/− mice (Zacchigna et al., 2009) were generated by Peter Carmeliet (Katholieke Universiteit, Leuven, Belgium), the TgN(GFAP-EGFP)Fki-GFEA mice (Nolte et al., 2001) were generated by Frank Kirchhoff (University of Saarland, Homburg, Germany) and the Nestin-GFP mice (Yamaguchi et al., 2000) by Masuhiro Yamaguchi (University of Tokyo). The GFAP-GFP and Prominin-1−/− transgenic mice were kindly supplied by Wieland B. Huttner from a colony maintained at the Max Planck Institute for Cell Biology and Molecular Genetics. All experiments were conducted in accordance with the applicable European and National regulations (Tierschutzgesetz) and approved by the responsible authority (Regierungspräsidium Dresden). Animals were maintained on a 12 h light/dark cycle with food and water provided ad libitum.

Total RNA isolation, cDNA synthesis, and quantitative PCR.

Total RNA was isolated from postnatal day 2 (P2), P3, P5, P10, P15, P20, and P30 hippocampus using the RNeasy minikit (Qiagen) according to the manufacturer's instructions. Reverse transcription was performed to synthesize cDNA using the SuperScript II system (Invitrogen). Quantitative PCR (q-PCR) was performed using the SYBR Green qPCR Supermix (Invitrogen). q-PCR primers were designed to amplify regions of the Prominin-1 gene. The PCR program consisted of 95°C for 15 min, followed by 45 cycles of 94°C for 15 s, 57°C for 30 s, and 72°C for 30 s. All gene amplification was standardized to a β-actin control. Gene expression was quantified as fold differences. Each sample was tested in triplicate, and data from at least three independent animals were used to calculate the means and SDs. The primer sequences can be found in Table 1.

Splice variant PCRs.

Total RNA was isolated from the dentate gyrus, SVZ, and kidney of adult C57BL/6 mice and cDNA prepared, as described above. PCRs were performed with primers designed to discriminate between the various mouse Prominin-1 splice variants. PCRs were performed using the PCR SuperMix (Invitrogen) and the PCR cycling conditions were as follows: 94°C for 5 min, followed by 35 cycles of 94°C for 30 s, 50°C for 30 s, and 72°C for 30 s. For the primer sequences and the splice variant they amplify see Table 1.

Brain tissue preparation.

Wild-type C57BL/6, Nestin-GFP, or GFAP-GFP mice (8 weeks old, males and females) were perfused transcardially with 0.9% NaCl followed by 4% paraformaldehyde (PFA). The brains were then removed and postfixed in 4% PFA overnight. After postfixation, the brains were cryoprotected by incubation overnight in 30% w/v sucrose in PBS until they sank. Frozen coronal serial sections (40 μm) were cut from a dry-ice cooled copper stage at a Leica table-top sliding microtome and stored at 4°C in cryoprotectant solution (25% ethylene glycol, 25% glycerol in 0.1 m phosphate buffer, pH 7.4).

Fluorescence-activated cell sorting.

C57BL/6, Nestin-GFP (Yamaguchi et al., 2000), or GFAP-GFP (Nolte et al., 2001) mice (8 weeks old; eight per experiment; males and females) were killed, their brains immediately removed, and the dentate gyri (Hagihara et al., 2009) and SVZ were microdissected. The tissue was enzymatically digested using the Neural Tissue Dissociation Kit (Miltenyi) according to the manufacturer's instructions. Following a final wash in HBSS (PAA; GE Healthcare) the pellet was resuspended in 1 ml of HBSS and filtered through a 40 μm cell sieve (Falcon; BD Biosciences). Cells were stained with a Prominin-1-specific antibody (13A4-Phycoerythrin (PE); eBioscience) and/or the CD24-Allophycocyanin (APC) (eBioscience) for 30 min at 4°C. Before adding the Prominin-1-PE or CD24-APC antibodies, a small proportion of the cells were removed and stained with an isotype control (Rat IgG1-PE or Rat IgG2bK-APC; eBioscience) as a control for nonspecific staining. The cells were finally washed in 10 ml of HBSS before being resuspended in 1 ml of HBSS for analysis by fluorescence-activated cell sorting (FACS). Cells were analyzed using a FACS Aria cell sorter (BD Biosciences). Dead cells were excluded by staining with propidium iodide (1 μg/ml).

Cell cycle analysis.

Cell cycle analysis was performed on Prominin-1-APC/Nestin-GFP stained cells using a combination of Pyronin Y (PY) and Hoechst 33342 to differentially stain DNA and RNA. Dentate gyri were dissected from eight Nestin-GFP mice (8 weeks old, males and females) and dissociated as described above. The cells were first washed in Hoechst staining buffer (HBSS containing 20 mm HEPES, pH 7.2, 1 g/L glucose, 10% fetal bovine serum, and 100 μm verapamil) then resuspended in staining buffer containing 1.6 μm Hoechst 33342. Following incubation for 45 min at 37°C in the dark, 3.3 μm PY was added and the cells incubated for a further 45 min at 37°C. The cells were washed with 10 ml of staining buffer and resuspended in 1 ml of staining buffer containing 5 μl of the Prominin-1-APC directly conjugated antibody and incubated at 4°C for 20 min. Following a final wash the cells were resuspended in 0.5 ml of staining buffer, passed through a 40 μm sieve, and analyzed by flow cytometry. Control tubes with each of the fluorophores stained individually were prepared (unstained, Nestin-GFP, Prominin-1-APC, Hoechst 33342, and PY) to set the compensation values.

Neurosphere culture.

Sorted populations of cells were collected directly into neurosphere growth medium and each population plated into 48 wells of a 96-well plate. Cells isolated from the Prominin-1 knock-out or wild-type mice were isolated and plated at a density of one SVZ or dentate gyrus per 96-well plate. The neurosphere growth medium consisted of mouse DMEM/F-12 basal medium (Gibco, Life Technologies) plus mouse NeuroCult NSC Proliferation Supplements (Stem Cell Technologies) with 2% bovine serum albumin (Gibco, Life Technologies), 2 μg/ml heparin (Sigma-Aldrich), and a final KCl concentration of 15 mm. The following growth factors were also included: 20 ng/ml purified mouse receptor-grade epidermal growth factor (EGF; BD Biosciences) and 10 ng/ml recombinant bovine FGF-2 (Roche). Cells were incubated in humidified 5% CO2 for 7 d for SVZ or 12 d for dentate gyrus to permit neurosphere formation. Approximately 16 h after sorting the cells were counted in at least six wells and the average cell number per well was determined. For the Prominin-1 knock-out mice dentate gyrus and SVZ tissue were dissected and dissociated as described above and plated in neurosphere medium at a density of the dentate gyri or SVZ or one animal per 96-well plate.

Neurosphere passaging and differentiation.

Primary hippocampal neurospheres were passaged by removing 150 μl of the medium from wells containing single large neurospheres, and treating with 100 μl of 0.05% trypsin- EDTA (Gibco) for 3 min room temperature, followed by washing with 100 μl of trypsin inhibitor (0.125 mg/ml trypsin inhibitor plus 0.01 mg/ml DNaseI) in DMEM. The neurospheres were mechanically triturated until dissociated and replated in 24-well plates in 2 ml of complete medium. Neurospheres were passaged every 10 d by removing the medium containing the neurospheres from the plates and centrifuging at 100 rcf for 7 min. The supernatant was then decanted, and the neurospheres were incubated in 1 ml of 0.05% trypsin-EDTA for 3 min at room temperature. After the addition of an equal volume of trypsin inhibitor, the neurospheres were centrifuged at 100 × g for 7 min and the supernatant was removed. Cells were mechanically triturated in 500 μl of complete medium and trypan blue staining was used to evaluate the number of cells, both viable and total number, on a hemocytometer. The passaged cells were then replated with complete medium at a density of 1 × 104 cells/cm2 in tissue culture flasks (Nalge Nunc International) or tissue culture plates (Falcon; BD Biosciences Discovery Labware) as appropriate. For differentiation, neurospheres were plated onto PDL and laminin-coated coverslips in DMEM/F-12 Basal Medium containing mouse NeuroCult NSC Proliferation Supplements without growth factors. The neurospheres were allowed to differentiate for 8 d in humidified 5% CO2 until flattened and adherent. The differentiated neurospheres were then fixed with 4% PFA in 0.1 m PBS at room temperature for 30 min. After washing with PBS, they were stained for either the neuronal markers βIII-tubulin or Map2ab, the astrocytic marker GFAP, the oligodendrocyte marker O4, or the precursor cell antigen Nestin, with a 4,6-diamidino-2-phenylindole (DAPI) counterstain to visualize the nuclei.

Adherent precursor cell line initiation and passaging.

Cells from the dentate gyrus of eight adult C57BL/6 mice were prepared and sorted by flow cytometry as described above. The primary cells from each sorted population were plated into one well of a 24-well plate (Falcon; BD Biosciences Discovery Labware) that had been coated with PDL (10 mg/ml) and laminin (10 mg/ml) in 2 ml of growth medium. The growth medium consisted of Neurobasal medium (Gibco, Life Technologies), supplemented with 2% B27 (Invitrogen), 1× GlutaMAX (Life Technologies), and 50 U/ml penicillin/streptomycin (Life Technologies). As growth factors 20 ng/ml EGF and 20 ng/ml FGF-2 were added for proliferation conditions. The growth medium was changed every 2–3 d and the cells passaged when they reached ∼80% confluency.

In vivo transplantation of Prominin-1+ precursor cells.

The dentate gyri from eight transgenic β-actin-GFP mice were dissected, dissociated, and stained with the Prominin-1-PE antibody as described above. The Prominin-1+ and Prominin-1− cells were isolated by FACS and collected into 5 μl of proliferation medium. Adult C57BL/6 mice were anesthetized via intraperitoneal injection of ketamine (50 mg/kg) and xylazine (8 mg/kg), mounted onto a stereotaxic frame (Stoelting), and a 1.5 cm skin incision was made to expose the skull. A hole was drilled in the skull directly above the dentate gyrus. Using a syringe (Hamilton) connected to a 30 gauge needle, two injections of 1 μl of the cell-containing medium were performed per hemisphere (anterior/posterior −1.3, medial/lateral +/− 1.0, dorsal/ventral −2.2; anterior/posterior −2, medial/lateral +/− 1.2, dorsal/ventral −2.2 relative to bregma). Following overnight recovery in the home cage the mice were transferred to a large cage (1 m2 floor area) containing environmental enrichment for 6 d, after which the mice were perfused and microtome sections were cut and stained for DCX, GFAP, Sox 2, NeuN, Olig2, NG2, or A2B5 as described above.

Bromodeoxyuridine injection.

To assess cell proliferation or neuronal survival in the neurogenic regions, Prominin-1+/+, Prominin-1+/− and Prominin-1−/− mice (8 weeks old, males and females) were given a single intraperitoneal injection of 50 mg/kg bromodeoxyuridine (BrdU; Sigma) and perfused either 2 h (proliferation) or 28 d later (neuronal survival).

Tissue processing and BrdU immunohistochemistry.

For immunohistochemistry, every sixth section was processed with BrdU immunohistochemistry. To assess proliferation, the sections were first washed thoroughly in TBS to remove the cryoprotectant solution. Pretreatment then consisted of incubations in 0.6% H2O2 for 30 min, washing with TBS and 0.9% NaCl, followed by DNA denaturation with 2.5N HCl for 30 min at 37°C. The sections were then washed in PBS and incubated in blocking solution containing 10% NDS and 0.2% Triton X-100 in TBS for 60 min at room temperature followed by incubation overnight at 4°C with a BrdU primary antibody (1:500; BD Bioscience) in blocking solution containing 3% NDS and 0.2% Triton X-100. The following day the sections were washed in PBS three times for 10 min, blocked for 30 min, and subsequently incubated for 2 h at room temperature with an anti-rat biotin secondary antibody (1:250; Jackson ImmunoResearch), diluted in blocking solution. diaminobenzidine detection was performed using the VECTASTAIN Elite ABC kit (Vector Laboratories) as per the manufacturer's instructions. After mounting in 0.1 m phosphate buffer onto gelatin-coated object slides, the sections were air dried and incubated in Neo-Clear (Merck Millipore) for 90 min. Coverslips were mounted using Neo-Mount (Merck Millipore) and dried at room temperature.

To assess net neuronal survival sections from mice injected with BrdU and killed 28 d later were processed for fluorescence staining with BrdU and Fox3 (NeuN). The sections were washed in PBS and incubated in blocking solution containing 10% NDS and 0.2% Triton X-100 in TBS for 60 min at room temperature followed by incubation overnight at 4°C with the BrdU (1:500; BD Bioscience) and NeuN (Fox3, 1:1000; Abcam) primary antibodies in blocking solution containing 3% NDS and 0.2% Triton X-100. The following day the sections were washed in PBS three times for 10 min, blocked for 30 min, and subsequently incubated for 4 h at room temperature with an anti-rat Alexa Fluor 488 and an anti-rabbit Cy3 secondary antibody (1:500; Jackson ImmunoResearch), diluted in blocking solution. Following three subsequent washes in PBS the sections were mounted onto glass slides using fluorescence mounting medium (DakoCytomation).

Data analysis.

Data analysis was performed using Prism software (Version 4.0c, GraphPad Software). Results were expressed as mean ± SEM. Statistical significance was determined using one-way or two-way ANOVA with a Tukey's post hoc test or Student's t tests as appropriate. The level of conventional statistical significance was set at p ≤ 0.05.

Results

Distinct splice variants of Prominin-1 are expressed in the adult SGZ

To determine whether the Prom1 gene is functional in the hippocampus we performed q-PCR using universal Prominin-1 primers designed to amplify all Prominin-1 splice variants identified to date (Fargeas et al., 2007). Interestingly, the comparison of the relative Prominin-1 expression at P2, P3, P5, P10, P15, P20, and adult revealed a stable expression of Prominin-1 transcripts in the maturing hippocampus from birth into adulthood (Fig. 1A).

Prominin-1 is expressed in the developing and adult hippocampus. A, q-PCR analysis revealed the relative Prominin-1 expression in the developing hippocampus from P2 until adulthood. Data represent the mean ± SEM (n = 4 independent animals per age group, not significant change in relative Prominin-1 expression with age; one-way ANOVA). B, Distinct Prominin-1 splice variants are expressed in the dentate gyrus and SVZ. PCRs were performed using cDNAs prepared from adult dentate gyrus, SVZ, and kidney as templates with specific sets of Prominin-1 primers. s1 to s8 refer to a given Prominin-1 splice variant. Arrow and arrowhead indicate s3 and s6 variants, respectively. L, 100 bp molecular weight ladder.

The Prominin-1 transcript has a great propensity for alternative splicing (Fargeas et al., 2004) and to date, eight alternative murine splice variants have been characterized (Fargeas et al., 2007). The Prominin-1 N and C termini are the major structural domains subjected to splicing. Two of these splice variants, s1 and s3, have previously been found in the adult mouse brain (Corbeil et al., 2009). In that study, it was shown that Prominin-1 s3 is expressed by cultured oligodendrocytes and might be a component of myelin, whereas the s1 variant is expressed by a subpopulation of GFAP-positive astrocytes (Corbeil et al., 2009). Using a combination of splice variant-specific primers we showed that a small facultative exon encoding 9 aa residues that could be either absent (e.g., s1 variant) or present (s2 variant) at the N-terminal domain (Yu et al., 2002) is detected in the adult SVZ, dentate gyrus, and kidney, suggesting that more than one splice variant can be simultaneously expressed (Fig. 1B). Interestingly, expression of the s6 variant, as defined by its C-terminal domain, appeared to be spatially restricted and could only be detected in the SVZ and kidney (Fig. 1B, arrowhead). In the dentate gyrus, the same primer pair could amplify only a smaller product corresponding to the C-terminal domain of either splice variant 3, 4, or 5 (Fig. 1B, arrow). The s8 variant, which to date has only been detected in the retina, could not be detected in either of the brain regions tested (Fig. 1B). Thus, particular areas of the adult brain (e.g., the dentate gyrus vs the SVZ) seem to express distinct Prominin-1 splice variants indicating a region-specific regulation of the Prom1 gene.

Given that we could detect the Prominin-1 transcript in the adult hippocampus we next wanted to determine the tissue localization of Prominin-1 at a protein level using the 13A4 mAb. Following our standard protocols for immunohistochemistry we could clearly detect Prominin-1 in the ependymal cells of the adult SVZ (Fig. 2A), in agreement with previous reports (Beckervordersandforth et al., 2010), but its expression appeared absent from the dentate gyrus. Using a refined immunohistochemistry protocol, in which we substituted Saponin for Triton X-100 as a detergent (Röper et al., 2000), in fact revealed Prominin-1 staining in the two neurogenic regions, the SVZ and the SGZ, albeit at very different levels of intensity. In the dentate gyrus, the intensity of the Prominin-1 immunoreaction was very low and only detectable upon close examination at high magnification (63×; Fig. 2B). This pattern suggested that although Prominin-1 is expressed in both neurogenic zones of the adult brain, the levels of expression are considerably different between them. In addition, in the hippocampus the exact cell types that were Prominin-1+ were difficult to determine due to the discrete membrane compartmentalization of the Prominin-1 and the high cell density in the SGZ. We also stained hippocampal sections from Nestin-GFP and GFAP-GFP transgenic mice with Prominin-1, which revealed Prominin-1 expression on both the Nestin+ precursor cells (Fig. 2C–E) and on GFAP+ “vertical” type-1 astrocytes or Type-1 cells (Fig. 2F). It has previously been shown that Prominin-1 is expressed by the cilia of astrocyte-like stem cells and ependymal cells of the SVZ (Beckervordersandforth et al., 2010). Using an antibody to detect the somatostatin receptor we were able to detect cilia-specific staining in the dentate gyrus (Fig. 2F″). However, the somatostatin receptor signal did not appear to colocalize with Prominin-1 staining in this region, indicating that in the dentate gyrus Prominin-1 is not expressed on the cilia. Colocalization of Prominin-1 expression with positive staining by the lectin wheat germ agglutinin, a carbohydrate binding protein that selectively recognizes sialic acid and N-acetylglucosaminyl sugar residues predominantly found on plasma membranes, confirmed the localization of the Prominin-1 immunoreactivity on membrane rather than intermediate filaments (Fig. 2E).

Prominin-1 is expressed in the adult SVZ and SGZ. Prominin-1 expression can be detected in the adult mouse SVZ (Prominin-1, red; GFAP, green; A) and SGZ (Prominin-1, green; GFAP, white; NeuN, red; B). Prominin-1 is expressed in the precursor cells of the dentate gyrus as evidenced by colocalization with the precursor markers Nestin (yellow; C, D), GFAP (magenta; C), and Sox2 (magenta; D). E, Prominin-1 (magenta) is expressed at the cell membrane as suggested by colabeling with the wheat germ agglutinin (blue). F, Prominin-1 is expressed by the “vertical” GFAP-GFP+ type-1 stem cells, but is not expressed on the cilium as evidenced by somatostatin receptor staining (F″). Arrows and arrowhead indicate Prominin-1 expression and somatostatin receptor 3 (Sstr3)+ cilium, respectively. Scale bars: 20 μm.

Prominin-1 is not only associated with plasma membrane protrusions (e.g., microvilli, primary cilia, midbodies), but is also released into the extracellular milieu in association with small (80 nm in diameter) or large (≈600 nm) membrane particles that originate from microvillus/primary cilium or midbody, respectively. The release of these Prominin-1-containing membrane particles occurs during the process of cellular differentiation. It therefore seemed possible that Prominin-1 could be found in small and large extracellular membrane particles since Prominin-1+ progenitor cells likely undergo a process of differentiation. However, the immunostaining of Prominin-1 that we detected (Fig. 2C–E′) was different from one in cleaved midbodies, which should appear as a ring-like structure (Marzesco et al., 2005; Ettinger et al., 2011; Kuo et al., 2011). Moreover, both types of extracellular membrane particles that have been described are much smaller than the Prominin-1 immunoreactivity detected in our study (1–3 μm).

Costaining of the Nestin-GFP sections with Prominin-1 in combination with another known stem cell marker, Sox2 (Fig. 2E), revealed that Prominin-1 is indeed expressed by the hippocampal precursor cells. A subset of Prominin-1+ cells in the dentate gyrus, however, was Nestin− and expressed S100β, a marker in the murine hippocampus found in postmitotic (“horizontal”) astrocytes. In the SVZ, ependymal cells are also S100β-positive (data not shown). Somewhat unexpectedly, a large number of DCX+/Nestin− (Type-3) cells in the SGZ also expressed Prominin-1 (data not shown).

Precursor cells can be prospectively isolated from the adult SVZ on the basis of coexpression of Prominin-1 and GFAP (Beckervordersandforth et al., 2010). This information, in combination with our detection of Prominin-1-expressing cells in the adult dentate gyrus, led us to next examine whether it would also be possible to prospectively isolate the hippocampal precursor cell population on the basis of Prominin-1. The dentate gyri from 8-week-old C57BL/6 mice were dissected, dissociated into a single-cell suspension, and stained with a PE-coupled Prominin-1 antibody. Dead cells and debris were excluded by gating the main cell population on the basis of forward and side scatter (Fig. 3A) and by staining with PI. The negative gates were set against unstained cells (Fig. 3B) and those cells stained with an isotype control (Fig. 3C). Importantly, we could confirm that the Prominin-1 antibody binding was specific; as cells isolated from the dentate gyrus of Prominin-1 knock-out mice showed no staining (Fig. 3D). Of the gated live cells ∼45% were labeled with Prominin-1 (Fig. 3E). The ability to accurately sort Prominin-1+ and Prominin-1− cells was confirmed by immediately resorting each population. Both populations showed >99% purity upon resorting.

Prospective isolation of Prominin-1+ cells from the adult dentate gyrus and SVZ. A, FACS plot of the gating based on forward and side scatter. B, The negative gate set by an unstained sample. C, The IgG1-PE isotype control antibody was used for nonspecific binding of the Prominin-1-PE antibody. D, Staining of cells derived from Prominin-1 knock-out (KO) mouse with the Prominin-1-PE antibody confirmed its specificity. E, Prominin-1 staining divides the cells into two approximately equal populations. E, inset, Example of Prominin-1+ staining on a dissociated FAC sorted dentate gyrus cell. Following a gating strategy based on unstained (F) and IgG1-PE isotype control stained (G) cells ∼40% of cells in the adult SVZ are Prominin-1+ (H).

Cells isolated from the adult SVZ were stained with the Prominin-1-PE antibody under the same conditions to compare the staining intensity and cell abundance of Prominin-1+ cells in the other major neurogenic region. When gated based on the unstained cells (Fig. 3F) and an isotype control (Fig. 3G) ∼40% of the SVZ cells stained positive for Prominin-1-PE (Fig. 3H). This Prominin-1+ cell frequency, as well as the relative staining intensity, was similar to cells isolated from the dentate gyrus.

Based on the immunohistochemical results in vivo, this large population of Prominin-1+ cells likely was heterogeneous, comprising a mix of stem and progenitor cells (Type-1 to -3) as well as astrocytes. The identity of the sorted Prominin-1+ cells was thus further analyzed with a number of cell-type-specific markers and flow cytometry. A large proportion (∼70%) of the Prominin-1+ cells was positive for S100β, which for the SGZ would indicate a population of astrocytes lacking precursor cell properties. In addition, a large proportion of the Prominin-1-expressing cells expressed GFAP and GLAST (45 and 75%, respectively), proteins that are highly expressed in astrocytes, and the astrocyte-like precursor cells. Nestin was also expressed by a subset of Prominin-1+ cells indicating that the hippocampal precursor cells, as defined based on their Nestin-expression (Yamaguchi et al., 2000), also express Prominin-1.

To examine whether the Prominin-1+ population contained the precursor cells, the sorted cell populations were grown under culture conditions, which enable single stem or progenitor cells to rapidly proliferate and form a large free-floating cluster of cells termed “neurosphere.” Using the neurosphere-forming assay one can quantitatively estimate the number of precursor cells in a given cell population. To this end, cells were plated at a very low density (<100 cells per well in a 96-well plate) and the number of neurospheres generated was quantified after 12 d of growth. Almost all of the neurospheres were formed from the Prominin-1+ population (94.1 ± 2.0% of the total neurospheres generated, n = 6 experiments), whereas the sorted cells negative for Prominin-1 generated only very few neurospheres (5.9 ± 2.0% of the total neurospheres generated). Remarkably, the neurosphere-forming frequency of the Prominin-1+ population was >30-fold enriched compared with the negative population (Prominin-1+: 1 in 115 cells, vs Prominin-1−: 1 in 3704 cells).

To further purify the hippocampal precursor population, cells expressing Nestin-GFP were stained with Prominin-1-PE and sorted. First, the precursor specificity of the GFP in the Nestin-GFP transgenic mice was examined. Nestin+ cells constituted ∼8% of total cells and generated 80.6 ± 16.5% of the total neurospheres (n = 4 experiments). Next, the Nestin-GFP cells were costained with the Prominin-1-PE antibody to determine whether colocalization of Nestin and Prominin-1 would further enrich the population of hippocampal precursor cells. The GFP gates were set based on a wild-type mouse (Fig. 4A) and staining with an isotype control antibody was used to set the PE gates (Fig. 4B). Four percent of all cells were positive for both Nestin and Prominin-1 (Fig. 4C). The growth of neurospheres from this small subset of cells confirmed that the majority of the neurosphere-forming cells were positive for both markers (70.9 ± 10.7 neurospheres generated per 1000 Nestin+/Prominin-1+ cells) compared with the Nestin+-only and Prominin-1+-only populations, which generated only a small number of neurospheres (Nestin+-only: 9.2 ± 2.5; Prominin-1+-only: 1.2 ± 0.3 neurospheres per 1000 cells; Fig. 4D).

FACS isolation and neurosphere-forming potential of Nestin and Prominin-1 double-positive cells. A–C, Four cell populations based on the expression of Prominin-1 and Nestin were isolated from Nestin-GFP transgenic mice by flow cytometry. A, A wild-type (WT) littermate was used to set the GFP gates. B, The IgG1-PE isotype control antibody was used to stain Nestin-GFP cells as a control for nonspecific PE binding. C, The FACS plot of the four populations gated based on Prominin-1-PE and Nestin-GFP expression. D, A histogram representing the number of neurospheres that were generated per 1000 cells for each isolated population. Data represent the mean ± SEM from three independent experiments, F(8) = 37.7, ***p ≤ 0.001, one-way ANOVA with Tukey's multiple-comparison test. Hoechst 33342/Pyronin Y cell cycle analysis on the Prominin-1+/Nestin+ (E), Prominin-1−/Nestin− (F), Prominin-1+/Nestin− (G), and Prominin-1−/Nestin+ (H) sorted cell populations.

To confirm the specificity of Prominin-1 expression in the Prominin-1+/Nestin+ population compared with the Nestin+-only population we examined the expression levels of the Prominin-1 splice variants s1 and s2 in these purified populations. Using the primer pairs mProm189F/mProm533R and mProm189F/mProm494R, we detected splice variants 1 and 2 in both populations. As expected, the double-positive population had much greater expression of both splice variants amounting to an ∼7-fold upregulation compared with the Nestin+/Prominin-1− cells (relative increase: 6.9 ± 4.5-fold, n = 2 individual FACS experiments, q-PCR triplicates). In addition, we confirmed that the Prominin-1+/Nestin+ population was indeed highly enriched for Prominin-1 mRNA expression with a >80-fold enrichment compared with the Prominin−/Nestin− population (relative increase: 82.6 ± 19.7-fold, n = 2 individual FACS experiments, q-PCR triplicates).

As the neurosphere experiments were performed under proliferation conditions it is difficult to determine whether the Prominin-1+/Nestin+ cell population contained the quiescent neural stem cells as well as the more highly proliferative progenitor cells. To address this we combined cell-surface staining (Prominin-1-APC staining of Nestin-GFP mice) with Hoechst 33342 and Pyronin Y staining. By staining with Hoechst and Pyronin Y we were able to differentiate between cells that were quiescent (G0: PY low) versus those that were cycling (G1: PY high). The Prominin-1/Nestin double-positive population described above amounted to only ∼4% of the total number of cells. In vivo a large number of the cells in this population were nondividing (quiescent) with 32% of the cells in the G0 phase as indicated by low levels of Pyronin Y staining (Fig. 4E). In addition, in accordance with our neurosphere data ∼40% of the cells in the Prominin-1+/Nestin+ population were actively dividing and stained strongly with the Pyronin Y dye. In contrast, the vast majority (>99%) of the cells in the negative population was in the G0 cell cycle phase and likely consisted of postmitotic neurons and astrocytes (Fig. 4F). The Prominin-1 and Nestin single-positive populations also contained a small number of cycling cells (4 and 6%, respectively), which are likely immature progenitor cells (DCX+) undergoing their last divisions and are not yet postmitotic (Fig. 4G,H).

Precursor cell-containing fractions are not the highest in Prominin-1 expression

Given the large and heterogeneous population of cells in the dentate gyrus that express Prominin-1, we divided the Prominin-1+ cells into three subpopulations on the basis of their relative levels of Prominin-1 expression. Cells with high levels of Prominin-1 expression represented ∼8%, intermediate (mid) 20% and low 15% of the total number of live cells (Fig. 5A). Interestingly, Prominin-1high cells did not generate any neurospheres (Fig. 5B) and all of the neurosphere-forming activity was found in the cells with lower levels of Prominin-1 (Prominin-1mid: 14.0 ± 3.7 neurospheres per 1000 cells; Prominin-1low: 28.1 ± 4.3 neurospheres per 1000 cells; Fig. 5B). When the neurosphere-forming frequency was expressed as a percentage of the total neurosphere number it became obvious that the majority of the neurospheres were generated from the Prominin-1mid population (Prominin-1mid: 53 ± 8.9% of total neurospheres formed; Prominin-1low: 42.9 ± 8.0% of total neurospheres formed; Fig. 5C). The classification of neurospheres into four size categories (40–70, 80–120, 130–190, and ≥200 μm) revealed no difference between those generated from Prominin-1mid and Prominin-1low subpopulations (no significant effect of cell population on neurosphere size in a two-way ANOVA F(8) = 0.13, p = 0.73, n = 5 individual FACS experiments; Fig. 5D).

Three Prominin-1+ cell populations can be isolated based on Prominin-1 expression level. A, The Prominin-1+ cells were divided by flow cytometry into three populations on the basis of Prominin-1 expression level. B, Histogram depicting the number of neurospheres formed per 1000 cells plated for each subpopulation. C, Histogram depicting the percentage of the total neurosphere number generated by each population. Data represent the mean ± SEM from n = 5 independent experiments F(160 = 21.9; *p ≤ 0.05, **p ≤ 0.01, ***p ≤ 0.001 one-way ANOVA with Tukey's multiple-comparison test. D, Histogram depicting the size distribution of the neurospheres generated from the Prominin-1mid and Prominin-1low populations. Data represent the mean ± SEM from n = 5 independent experiments, two-way ANOVA no significant effect of population F(8) = 0.13, p = 0.73.

As the Prominin-1high cells were not precursor cells, we next wanted to determine which other cell type would constitute the majority of that population. Using a combination of GFAP-GFP, the EGF receptor, and Heat Stable Antigen (CD24) it has been reported that astrocytes (GFAP+EGFR−CD24−), stem cells (GFAP+EGFR+CD24−), transit-amplifying cells (GFAP−EGFR+CD24−), “neuroblasts” (GFAP−EGFR−CD24low), and ependymal cells (GFAP−EGFR−CD24high) can be simultaneously isolated from the adult SVZ (Pastrana et al., 2009). We thus made use of a similar strategy to determine the cell type that constituted the majority in each of the three Prominin-1 subpopulations of our experiment. We isolated the dentate gyrus from GFAP-GFP transgenic mice, stained the dissociated cells with both Prominin-1 and CD24, and characterized them using flow cytometry. Interestingly, the four Prominin-1 subpopulations each displayed very specific expression profiles for these markers. The Prominin-1high population contained no GFAP+CD24− cells, but instead ∼35% GFAP−CD24low cells (Fig. 6A). The Prominin-1mid population in contrast, contained 12% (Fig. 6B) and the Prominin-1low population 11% GFAP+CD24− cells (Fig. 6C), but only a small number of GFAP−CD24low cells (6 and 8%, respectively). Similar to the Prominin-1high fraction, the Prominin-1neg population contained very few GFAP+CD24− cells (1%; Fig. 6D). Together, these data supported our in vitro findings that the putative stem cell population (GFAP+CD24−) can be found in the population of cells with medium-to-low levels of Prominin-1 expression. Additionally, we sorted cells on the basis of these three markers and collected four populations (GFAP+Prominin-1+CD24−, GFAP+Prominin-1−CD24−, GFAP−Prominin-1−CD24−, and GFAP−Prominin-1+/−CD24low) and again cultured these as neurospheres. As expected the majority of the neurosphere-forming activity was found in the GFAP+Prominin-1+CD24− population (86.2 ± 5.0% of total neurosphere number; n = 3 experiments).

Cells with the highest levels of Prominin-1 are GFAP−/CD24low. The Prominin-1high, Prominin-1mid, Prominin-1low, and Prominin-1neg populations were each examined for their expression of the markers GFAP-GFP and CD24. In contrast to the other populations, a large proportion (35%) of the Prominin-1high cells were GFAP−/CD24low (A). In contrast to the Prominin-1high population that contained no GFAP+ cells, the Prominin-1mid and Prominin-1low populations consisted of ∼12% GFAP+ cells (B, C). Similar to the Prominin-1high cells, the Prominin-1neg population contained no GFAP+ astrocytes/precursor cells (D).

Prominin-1mid/low expression marks neural stem cells

We next confirmed that the Prominin-1+ cells could also be cultured efficiently as adherent monolayer cultures (Babu et al., 2007). Prominin-1high, Prominin-1mid, Prominin-1low, and Prominin-1neg cells were sorted and each population was plated into a single PDL/laminin-coated well and cultured. In agreement with the results generated from the neurosphere assays, cell proliferation was observed only from the Prominin-1mid (Fig. 7A) and Prominin-1low cultures, whereas no growth occurred from the Prominin-1high or Prominin-1neg cells (Fig. 7B). After having been kept under proliferation conditions for four passages, >95% of cells were positive for Nestin and Sox2 indicating that they have maintained their immunohistochemical stem cell properties (Fig. 7C).

Prominin-1+ cells are multipotent in vitro. Prominin-1high, mid, low, neg cells were sorted and then cultured independently as adherent monolayer cultures (A–C, G) or neurospheres (D–F). Cell proliferation was observed only from the Prominin-1mid (A) and Prominin-1low cultures, with no growth from the Prominin-1high (B) or Prominin-1neg cells. C, After five passages under proliferation conditions the majority of the cells stained positive for the precursor markers Nestin (green) and Sox2 (red) and upon differentiation Prominin-1mid cells could generate GFAP+ astrocytes and βIII-tubulin+ neurons (G). Likewise, primary neurospheres generated from the Prominin-1-expressing cells can differentiate into βIII-tubulin+ (D) and Map2ab+ (E) neurons, GFAP+ astrocytes (D, E), and O4+ oligodendrocytes (F). Scale bars: 40 μm.

Marker expression and sphere-forming capability supported the idea that a fraction of the Prominin-1+ cells act as precursor cells. The next question was, whether they also met the specific criteria for stem cells. To examine which neurospheres were stem cell derived, we assessed multipotentiality and self-renewal. We first examined multipotentiality by differentiating the primary neurospheres generated from the Prominin-1-expressing cells in the absence of mitogens for 7 d, followed by staining with the neuronal markers βIII-tubulin and Map2ab, the oligodendrocyte marker O4, and the astrocyte marker GFAP. This study revealed that while the majority of the neurospheres generated only glia, a small number of them gave rise to all three cell types (Fig. 7D–F). Quantification of the percentage of β-tubulin+ neurons, GFAP+ astrocytes, and O4+ oligodendrocytes revealed no significant difference in the differentiation potential between the Prominin-1mid- and Prominin-1low-derived neurospheres (Prominin-1mid: 8.9 ± 0.7% neurons, 69.3 ± 2.8% astrocytes, 1.9 ± 0.4% oligodendrocytes vs Prominin-1low: 7.4 ± 2.0% neurons, 68.9 ± 3.6% astrocytes, 1.9 ± 0.3% oligodendrocytes; no significant effect of cell population on differentiation potential in a two-way ANOVA F(77,1) = 0.18, p = 0.67, n ≥14). To examine their self-renewal capacity, individual large (>200 μm) primary neurospheres were dissociated into single cells, replated into neurosphere medium, and cultured as individual cell lines. This process was repeated every 10 d up to passage number five after which the number of lines that could be maintained was recorded. Consistent with our previous data (Walker et al., 2008), a small number of these primary neurospheres could be maintained over five passages (10/67 neurospheres), indicating their propensity for self-renewal.

Additionally, the adherent monolayer cultures generated from the Prominin-1mid and Prominin-1low cells were passaged and then differentiated in vitro to examine self-renewal and multipotentiality. Following five passages the cells were plated in differentiation conditions in the absence of mitogens (for 5 d), after which they were fixed and stained. Following 5 d under differentiation conditions, both GFAP+ astrocytes and βIII-tubulin+ neurons could be found (Fig. 7G).

In vivo homing of Prominin-1+ cells

Next we investigated whether isolated Prominin-1+ cells that behaved as precursor cells ex vivo would upon re-implantation show a preference for the neurogenic niche within the SGZ. Prominin-1+ cells were isolated from the dentate gyrus of β-actin-GFP reporter mice by flow cytometry using Prominin-1-PE. Again, three subpopulations of Prominin-1 were isolated based on its expression level: high, mid, and low. Prominin-1+/β-actin-GFP+ cells were then injected directly into the hippocampus of host C57BL/6 mice. Note that sorted primary cells were used immediately after isolation rather than cultured neurospheres to eliminate the possibility that their survival was influenced by exposure to growth factors or extensive culture in vitro. The transplanted mice were kept in environmental enrichment for 6 d and the fate of the transplanted cells was assessed. Microscopic examination of every third section revealed a small number of bright GFP+ cells that had survived in the dentate gyrus (Fig. 8A), the corpus callosum (Fig. 8B), or the hippocampal fissure (Fig. 8C). At this stage, these cells were not positive for DCX or GFAP (Fig. 8D), NeuN, NG2, Olig2, A2B5, or Sox2. Fitting with their precursor cell phenotype, the majority of the surviving cells from the Prominin-1mid and Prominin-1low cell transplantations were located within the SGZ (Prominin-1mid: 58.3 ± 30.0%, Prominin-1low: 87.5 ± 12.5% of total surviving cells per transplantation; Fig. 8E). This is in contrast to the Prominin-1high cells, which preferentially survived in the hippocampal fissure (95.8 ± 4.2%; n = 3 independent experiments per cell population; significant interaction between cell population and brain region in a two-way ANOVA F(18) = 9.5, p = 0.0003; Fig. 8E).

In vivo homing of Prominin-1+ cells. Six days following the transplantation of primary sorted Prominin-1+/β-actin-GFP+ cells into the adult brain, live GFP+ cells are localized to the dentate gyrus (A), the corpus callosum (B), or the hippocampal fissure (C). D, These GFP+ transplanted cells are not yet positive for DCX (red) or GFAP (white). Scale bars: 20 μm. E, The majority of the Prominin-1low and Prominin-1mid cells survive in the dentate gyrus whereas the majority of the Prominin-1high cells migrate to the hippocampal fissure. n = 3 independent transplantation experiments for each of the cell populations. DG, dentate gyrus; CC, corpus callosum; HF, hippocampal fissure. Data represent the mean ± SEM, significant interaction between cell population and brain region in a two-way ANOVA (F(18) = 9.5, p = 0.0003).

Knock-out of Prominin-1 affects survival but not proliferation of adult born hippocampal precursor cells

The Prominin-2 transcript is upregulated in the dentate gyrus of Prominin-1-null mice

Prominin-2 is the second pentaspan membrane glycoprotein that is structurally related to Prominin-1 (Fargeas et al., 2003). Both proteins share a number of important biochemical and morphological properties, including their selective concentration in plasmalemmal protrusions and their association with detergent-resistant membranes in a cholesterol-dependent manner (Fargeas et al., 2003; Florek et al., 2007). Therefore, it has been suggested that this may lead to a redundancy in their role as organizers of plasma membrane protrusions (Florek et al., 2007). To test whether, assuming shared functionality, Prominin-2 might compensate for the loss of Prominin-1 in the hippocampal precursor cells of Prominin-1 knock-out mice, we first confirmed the expression of Prominin-2 mRNA in the dentate gyrus. Reverse transcriptase PCR analysis with Prominin-2-specific primers (Table 1), designed to span an intron to eliminate amplification from genomic DNA, amplified the expected product from the dentate gyrus cDNA (data not shown). Given that Prominin-2 was thus expressed in the proper location, we hypothesized that if Prominin-2 is compensating for the lack of Prominin-1 expression, then the relative expression of Prominin-2 should increase in the Prominin-1-null mice compared with their wild-type counterparts. Indeed, Prominin-2 expression was ∼35% higher in the Prominin-1-null mice compared with their wild-type littermates (135.4 ± 10.7%, t test p = 0.03, n = 6 mice per genotype).

Discussion

Despite the large body of literature on Prominin-1 in other brain regions (Weigmann et al., 1997; Corti et al., 2007; Pfenninger et al., 2007), there was very little information on Prominin-1 in the adult SGZ. In this study, we show that neural stem cells in the dentate gyrus of adult mice express Prominin-1, which is consistent with our earlier data showing a genetic association between its expression and neurogenesis in the adult hippocampus (Kempermann et al., 2006).

Our findings suggest that Prominin-1 expression and function in the SGZ might be similar to, but also differ from, other compartments. To further address such tissue compartmentalization, we evaluated which murine splice variants were expressed. We identified Prominin-1 splice variants, in which the small facultative exon at the N-terminal domain is present (s2) or absent (s1), in both the SVZ and SGZ. Likewise, we could amplify a product potentially corresponding to the C-terminal domain of the s3 from the dentate gyrus, although this primer set could not differentiate among the s3, s4, and s5. Given that s4 and s5 variants do not traffic out of the endoplasmic reticulum upon ectopic expression (Fargeas et al., 2004), our data suggest that s3 is indeed found in the dentate gyrus. In contrast, the s6 variant is found solely in the SVZ but not the SGZ. The ependymal cells where a high level of Prominin-1 is detected may express this splice variant.

In addition to detection of Prominin-1 transcripts, we also localized Prominin-1 protein in the adult SGZ in vivo. As described for other somatic stem cells in different organ systems, the expression of Prominin-1 allowed us to isolate potential precursor cells from the adult hippocampus. Upon dissociation and flow cytometry three distinct cell populations were classified according to their levels of Prominin-1 immunoreactivity levels. Interestingly, those cells with mid-to-low levels of Prominin-1 contained the precursor cells, while the cell fraction with the highest level of Prominin-1 was devoid of precursor cells. This is in accordance with a previous report that embryonic day 13.5 mouse cortical cells with low levels of Prominin-1 could be identified as multipotent stem cells, whereas those with the highest levels were neuronal progenitor cells (Panchision et al., 2007). From the total number of Prominin-1+ cells only 1 of 115 formed a neurosphere. In contrast, ∼1 of 70 cells in the Prominin-1mid and 1 of 35 cells from the Prominin-1low populations generated a neurosphere. To further purify the precursor population, Prominin-1 staining was performed on Nestin-GFP transgenic mice (Yamaguchi et al., 2000). Despite the extensive characterization of the Nestin+ hippocampal cells in this transgenic line (Sawamoto et al., 2001b; Filippov et al., 2003; Fukuda et al., 2003; Kempermann et al., 2003; Kronenberg et al., 2003) and their use to isolate precursor cells from brain tissue (Sawamoto et al., 2001a), there have not been any reports on using this mouse to specifically extract precursor cells from the hippocampus. We isolated Nestin-GFP+ cells by flow cytometry and demonstrated that Nestin is not specific for the Type-1 and Type-2a precursor cells when used alone. In our hands only 1 of 30 Nestin+ cells formed a neurosphere in vitro. However, by combining Prominin-1 staining with Nestin-GFP expression we enriched for the precursor cells by removing over half of the non-neurosphere-forming cells that are Nestin+ but Prominin-1−, increasing the purity twofold to ∼1 of 14 cells. From the Prominin-1+/Nestin+ population we could generate self-renewing, multipotent neurospheres that differentiated into the three neural lineages, thereby satisfying the cardinal criteria of stemness. In addition, cell cycle analysis revealed that a large proportion of these cells were actively dividing.

Despite the fact that the precursor cells of the adult dentate gyrus express Prominin-1, its expression was not limited to the precursor cells in vivo. FACS analysis revealed that a large number of the Prominin-1+ cells expressed the common astrocyte markers S100β, GFAP, and GLAST as well as the intermediate progenitor cell marker DCX. In the SVZ, the majority of the Prominin-1+ cells are ependymal cells (∼90% expressed the markers S100β and the cilia-associated protein acetylated tubulin) and, in addition, this population was reported to contain neither neuroblasts nor transiently amplifying cells (Beckervordersandforth et al., 2010). In the SGZ a quite different situation became evident. In contrast to the SVZ, the dentate gyrus contains no multiciliated ependymal cells but many cells types have been reported to have cilia including both the stem cells (Breunig et al., 2008) and mature neurons (Kumamoto et al., 2012).

To gain insight into the major cell types constituting each of the Prominin-1 populations in the SGZ we used a similar approach to that previously used for the SVZ (Pastrana et al., 2009). We saw very different expression profiles for the GFAP-GFP and CD24 markers in the Prominin-1 populations. Interestingly, in contrast to the ependymal cells of the SVZ (GFAP−CD24high), the cells with the highest levels of Prominin-1 expression were GFAP− CD24low, a marker combination that in the SVZ is considered to identify neuroblasts (or “A-cells”). No strict equivalent to this cell type exists in the SGZ and the onset of CD24 expression during neuronal development is unknown. However, CD24 is expressed by differentiating neurons in the adult hippocampus and CD24-deficient mice show increased precursor cell proliferation and adult hippocampal neurogenesis (Belvindrah et al., 2002), suggesting that CD24 might negatively regulate precursor cell proliferation. The highly proliferative precursor cells (Type-2a and -2b) should, accordingly, have low levels of CD24. The Type-1 stem cells of the SGZ express high levels of GFAP, whereas the Type-2a cells have low or absent GFAP expression. In contrast to the Prominin-1high and Prominin-1neg populations, which contained virtually no GFAP+CD24− cells, the Prominin-1mid/low populations contained a large number of this cell type. The Prominin-1mid/low cells that are GFAP+CD24− contain astrocytes—a small proportion of which are the GFAP+ stem cells. As expected the precursor activity was found only in this GFAP+Prominin+CD24− subpopulation.

Although a panel of specific cell-surface markers is available for the purification of hematopoietic stem cells, the development of markers capable of identifying and isolating defined neural stem cell populations lags behind. Despite the fact that neurogenesis in the hippocampus is well characterized with respect to the expression of characteristic antigens there seems to be a distinct lack of appropriate surface markers for the isolation of the resident stem cells. There have been only a few reports all of which made use of transgenic reporter mice, i.e., DCX-GFP (Walker et al., 2007), Hes5-GFP (Jhaveri et al., 2010), Nestin-GFP (Gao et al., 2008), Sox2-EGFP (Brazel et al., 2005), and Sox-2-GFP/DCX-DsRed (Bracko et al., 2012). The identification of surface markers is important to reduce the dependence on reporter mouse lines, allowing specific cell populations to be isolated from any mouse strain, including transgenic or knock-out mouse models, and the translation of the technology to other species such as rats or humans.

Although Prominin-1 is expressed by the stem cells of the adult SGZ, its absence in Prominin-1 knock-out mice had no obvious effect on precursor cell proliferation. Interestingly, however, we found a significant reduction in the number of new neurons surviving in the Prominin-1 knock-out mice. This is in accordance with previous studies showing that Prominin-1 knockdown does not affect proliferation of colon cancer cells in vitro (Horst et al., 2009) but may be important in for the survival of the tumor seeding cells (Canis et al., 2012). Effects of Prominin-1 on apoptosis were excluded given that no difference was observed in the cleavage of caspase-3 (Horst et al., 2009). It is likely that the closely related family member Prominin-2 compensates for the loss of Prominin-1 as its mRNA expression was upregulated in the hippocampus of Prominin-1 knock-out mice. This situation is particularly interesting since the loss of Prominin-1 in the murine retina, which leads to blindness, is not compensated by Prominin-2 (Zacchigna et al., 2009). Moreover, the absence of Prominin-2 in normal retina (Fargeas et al., 2003) might explain the predominant retinal phenotypes observed in individuals carrying mutations in the Prom1 gene (Jászai et al., 2007; Arrigoni et al., 2011). To confirm this would require the generation of Prominin-1/Prominin-2 double knock-out mice or a Prominin-2 floxed mouse to delete Prominin-2 specifically in the adult brain of Prominin-1-deficient mice. Those experiments are ongoing.

In summary, we have shown that the cell-surface antigen Prominin-1 can be used to enrich precursor cells from the adult murine dentate gyrus. In addition, we have described novel marker combinations (Nestin/Prominin-1 and GFAP-GFP/Prominin-1/CD24) for the simultaneous flow cytometric isolation of multiple cell types from the adult SGZ. This approach will facilitate the isolation and characterization of homogeneous cell populations of astrocytes, neural precursor cells, and immature neurons to gain a deeper understanding of the underlying molecular regulation of hippocampal neurogenesis in response to activity or injury in individual cell types rather than at the level of the entire dentate gyrus.

Footnotes

This work was supported by a Marie Curie International Incoming Fellowship (T.L.W.), the 2011 William P. Van Wagenen Fellowship Award from the American Association of Neurological Surgeons (B.W.), and by long-term structural funding—Methusalem funding by the Flemish Government—and by Grant FWO G.0209.07 of the Flemish Government (P.C.). This project was financed from basic institutional funding and partly with support from Priority Research Program (SFB) 655 to G.K. and D.C. We thank Anne Karasinsky for care and maintenance of all animals used in this study and Nicole Rund and Katja Schneider for assistance with FACS.